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Mitogen Activated Protein Kinase Signaling
in the Heart: Angels Versus Demons in a
Heart Breaking Tale
Abstract
Among the myriad of intracellular signaling networks that govern the cardiac development and pathogenesis,
mitogen-activated protein kinases (MAPKs) are prominent players that have been the focus of extensive
investigations in the past decades. The four best characterized MAPK subfamilies, ERK1/2, JNK, p38, and ERK5,
are the targets of pharmacological and genetic manipulations to uncover their roles in cardiac development, function,
and diseases. However, information reported in the literature from these efforts has not yet resulted in a clear view
about the roles of specific MAPK pathways in heart. Rather, controversies from contradictive results have led to a
perception that MAPKs are ambiguous characters in heart with both protective and detrimental effects. The primary
object of this review is to provide a comprehensive overview of the current progress, in an effort to highlight the
areas where consensus is established verses the ones where controversy remains. MAPKs in cardiac development,
cardiac hypertrophy, ischemia/reperfusion injury, and pathological remodeling are the main focuses of this review as
these represent the most critical issues for evaluating MAPKs as viable targets of therapeutic development. The
studies presented in this review will help to reveal the major challenges in the field and the limitations of current
approaches and point to a critical need in future studies to gain better understanding of the fundamental mechanisms
of MAPK function and regulation in the heart.
Previous SectionNext Section
I. INTRODUCTION
Cellular responses to various stimuli are mediated via complex but coordinated signaling pathways. In the heart, a
cast of molecules participate in a choreographed drama of signal transduction events during cardiac development,
physiological adaptation, and pathological manifestation. Mitogen-activated protein kinases (MAPKs) are a well-
studied family of proteins that play an integral role in these signaling events. Like any good drama, MAPK members
consist of both angels and demons that can protect or injure the heart. In this review, we focus on our current
understanding of the roles these different MAPK members play in cardiac development, function, and diseases and
discuss efforts to harness their activities to treat heart failure.
Highly conserved from yeast to human (429), MAPKs are involved in a diverse repertoire of biological events
including proliferation, differentiation, metabolism, motility, survival, and apoptosis. These biological events are the
culmination of signal transduction and regulation by primarily four MAPK subfamilies including extracellular
signal-regulated kinases (ERK1/2), c-Jun NH2-terminal kinases (JNK1, -2 and -3), p38 kinase (, , , ), and bigMAPK (BMK or ERK5) (185,318,329). Activation of MAPKs requires dual phosphorylation of a Thr-X-Tyr motif
(where X is either a Gly, Pro, or Glu) in the regulatory loop (62,330). The typical event leading to this
phosphorylation is a well-conserved three-tiered kinase cascade in which a MAPK kinase kinase (MAPKKK,
MAP3K, MEKK, or MKKK) activates a MAPK kinase (MAPKK, MAP2K, MEK, or MKK) which in turn activates
the MAPK through serial phosphorylation (Fig. 1). This canonical activation cascade allows for signal amplification,
modulation, and specificity in response to different stimuli (120). As with many signaling pathways, complex
regulatory mechanisms are utilized to direct the functional outcome mediated by MAPKs. The prototypic ERK1/2
pathway is found to be mainly responsive to stimulation by growth factor s (333), while JNK and p38 are collectively
called stress-activated MAPKs (SAPKs) due to their induction by physical, chemical and physiological stressors
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[such as ultraviolet (UV) light, oxidant stress, osmotic shock, infection, and cytokines] (221). In addition, the
ERK5/BMK pathway is implicated in both growth and stress signaling (155). The specificity and efficiency of
MAPK signaling pathways are often dictated by specific docking and binding partners (180,332,336). These
include positive and negative modulators and scaffolding proteins which help to bring upstream and downstream
signaling components together (95,285,318). On the other hand, selective interaction between the MKK's docking
sites (D sites) and their cognate MAPKs helps to segregate different branches of MAPKs into specific signaling
pathways (2729,143,163,336). Once activated, MAPKs can phosphorylate serine or threonine residues in a
specific Pro-X-Thr/Ser-Pro motif on their target proteins (377). The duration and level of MAPK signaling are
subject to negative-feedback regulation by Try, Ser/Thr, or dual-specificity phosphatases (261,311). The resulting
balance between kinase activation and inactivation by these phosphatases adds yet another layer of regulation by
which MAPK signaling is tightly controlled to achieve the desired outcome. While there is a large degree of
specificity in different MAPK cascades, there is also significant overlap observed among them. Both upstream
activators and downstream targets can be shared between different subfamilies, allowing for potential cross-talk and
feedback (329,411). Likewise, some phosphatases activated by one pathway (e.g., protein phosphatase 2A
stimulation by p38) can act as a negative regulator of another pathway (e.g., ERK), demonstrating the close
connection between different signaling events of MAPK family members (186). Furthermore, in addition to the
classic kinase phosphorylation cascades just discussed, several noncanonical mechanisms have also been identified
for MAPK activation, adding to the molecular complexity of MAPK signal transduction (348). In short, MAPKs
form complex signaling networks that can be induced by a large array of external stimuli and can achieve highly
specific cellular effects through multitudes of regulatory mechanisms.
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Fig. 1.
Canonical mitogen-activated protein kinase (MAPK) signaling. MAPK are prototypically activated by canonical
three-tiered sequential phosphorylation events. The most well-known MAPKKK and MAPKK are listed for each
MAPK; however, this is only a small representation of all identified upstream kinases. Furthermore, multiple steps
may exist between the cell stimulus and activation of the MAPKKK and between activation of the MAPK and the
biological response.
Previous SectionNext Section
II. MITOGEN ACTIVATED PROTEIN KINASE FAMILY MEMBERS
There are four classic MAPK subfamilies. Each of these family members has been studied extensively in a multitude
of cellular settings and has been reviewed in great detail by others (31,221,318,332,333,348). For this reason,
only a brief introduction to each subfamily will be given here. Furthermore, other atypical MAPKs, including
ERK3/4, NLK, and ERK7, are much less studied and are not discussed in this review (81).
A. ERK1/2
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First discovered in the early 1980s for its ability to phosphorylate microtubule-associated protein-2 (MAP-2) in 3T3-
L1 adipocytes in response to insulin stimulation (18), extracellular signal-regulated kinases (ERKs) are now one of
the most widely studied signaling pathways in cellular biology. ERK1 and ERK2 are 83% identical, share most of
the same signaling activities, and, as a result, are usually referred to simply as ERK1/2. However, these two proteins
are not completely functionally redundant as demonstrated by gene knockout experiments. ERK1 null mice have, in
general, a normal phenotype (139,312), but ERK2 null mice are embryonic lethal between E6.5 and E8.5
(139,151,350,454). ERK1/2 is ubiquitously expressed and has many diverse cellular and physiological functions.
At the cellular level, ERK1/2 regulates cell cycle progression, proliferation, cytokinesis, transcription,
differentiation, senescence, cell death, migration, GAP junction formation, actin and microtubule networks, and cell
adhesion (333). ERK1/2's role in cellular biology translates it into a prominent player in physiological settings,
influencing the immune system and heart development and contributing to the response of many hormones, growth
factors, and insulin. Furthermore, because of its role in so many biological processes, ERK1/2 has likewise been
shown to play a significant part in various pathologies including cancer, diabetes, and cardiovascular disease. This
extensive and diverse functional ability is the result of ERK1/2's ability to phosphorylate over 100 possible
substrates (456).
As discussed previously, ERK1/2 is activated via a canonical three-tiered kinase cascade by both extracellular and
intracellular stimuli (Fig. 2A). Growth factors, serum, and phorbol esters strongly activate the pathway, but it can
also be activated by G protein-coupled receptors, cytokines, microtubule disorganization, and other stimuli
(140,270,332). Prototypically, growth factor (such as fibroblast growth factor, FGF) binding to their respective
receptor tyrosine kinase (RTK) activates Ras which recruits and activates Raf (MAP3K) at the plasma membrane.
Once activated, Raf phosphorylates and activates MEK1/2 (MAP2K). MEK1/2 in turn activates ERK1/2 byphosphorylation of the Thr and Tyr residues in the conserved Thr-Glu-Tyr motif within its regulatory loop.
Activated ERK1/2 can phosphorylate downstream proteins in the cytoplasm or nucleus, including many
transcription factors.
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Fig. 2.Representative MAPK signaling in the heart. MAPK signaling events that play a role in cardiac signaling. Not all
connections necessarily represent a direct interaction but rather may represent the end product of multiple steps.
These are only a general representation of a sample of signaling events in the heart and do not represent all known
MAPK signaling. A: ERK signaling. B: JNK signaling. C: p38 signaling. D: ERK5 signaling.
As mentioned in section I, MAPK signaling is subject to many mechanisms of modulation that determine the
specificity and magnitude of the signaling outcome. Interactions with scaffold proteins are one of these mechanisms.
ERK has a number of known scaffold proteins including kinase suppressor of Ras (KSR), MEK partner 1 (MP1),
MAPK organizer 1 (MORG1), and -arrestin (95). Structural studies also reveal specific docking site motifs that
help direct the specificity of ERK1/2 signaling, including the ERK docking (ED) motif, the docking site for ERK
and FXFG (DEF) motif, and the common docking (CD) motif (332). Protein phosphatases are a third mechanism
that contributes to MAPK regulation. ERK signaling has been shown to be regulated by various phosphatases
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including dual-specificity MAPK phosphatases (MKP1,-2, -3, and -4), protein serine/threonine phosphatases (PP2A,
PPM1), and protein tyrosine phosphatases (SHP-2 PTP, hematopoietic PTP, STEP, PTP-) (186,311). The final
way that MAPK activity is regulated is by positive and negative feedback regulation from other components of the
MAPK signaling network. This includes negative regulation of ERK by other MAPKs such as JNK and p38 (186).
B. JNK
In the early 1990s, 10 years after the discovery of ERK, JNK was discovered as a second subfamily of MAPKs forits ability to phosphorylate microtubule-associated protein 2 in rat liver following cycloheximide injection. It was
further detailed for its ability to phosphorylate the transcription factor c-jun at two sites following UV radiation
(159,219,220). JNK1, JNK2, and JNK3 are encoded by three separate genes, and alternative splicing can produce
10 different protein sequences that share >80% homology (31). JNK1 and JNK2 are ubiquitously expressed, while
JNK3 is predominantly found in the brain, heart, and testis (93). While there is some redundancy in the functions of
the three isoforms, gene knockout studies have shown specific roles for different JNK isoforms in vivo (41,139).
Like ERK, JNK plays a role in a number of different biological processes including cell proliferation,
differentiation, apoptosis, cell survival, actin reorganization, cell mobility, metabolism, and cytokine production
(43,93,332). This translates into JNK's physiological role in insulin signaling, the immune response and
inflammation, and its pathological role in neurological disorders, arthritis, obesity, diabetes, atherosclerosis, cardiac
disease, liver disease, and cancer (41).
Activation of the JNK pathway occurs in response to a number of different stimuli. As a stress-activated protein
kinase, JNK responds most robustly to inflammatory cytokines and cellular stresses such as heat shock,hyperosmolarity, ischemia-reperfusion, UV radiation, oxidant stress, DNA damage, and ER stress (41,332).
However, they are also activated to a lesser extent by growth factors, G protein-coupled receptors, and noncanonical
Wnt pathway signaling (140,196,317). Once stimulated, JNK is activated by the previously described three-tiered
kinase cascade (Fig. 2B). After the cell is stimulated, signaling occurs which eventually leads to the activation of the
first tier. The MAP3Ks that can activate JNKs are MEKK1, MEKK2, and MEKK3, as well as mixed lineage kinase
2 and 3 (MLK2 and MLK3) and others (332). These kinases then activate the MAP2Ks involved in the JNK
cascade, MKK4 and MKK7. MKK4/7 then activates JNK by phosphorylation on a conserved Thr-Pro-Tyr motif. It
has been shown that MKK4 has a preference for Tyr phosphorylation while MKK7 has a preference for Thr in the
TPY motif, allowing these two kinases to work synergistically in JNK activation (227). Activated JNK has a large
number of downstream substrates, including nuclear and cytoplasmic proteins. Similar to the other MAPKs, JNK
has the ability to shuttle between the cytoplasm and the nucleus to exert its effects depending on the specific cellular
stimuli. The diversity of JNK signaling can be conferred by signaling via more than 25 nuclear substrates and more
than 25 nonnuclear substrates for any specific stimulus (43).JNKs, like all MAPKs, utilize the same mechanisms to impart specificity and degree of magnitude to its signaling.
Interaction with scaffold proteins such as JNK-interacting proteins (JIP1, JIP2), JNK/stress-activated protein kinase-
associated protein 1 (JSAP1/JIP3), JNK-associated leucine-zipper protein (JLP), and plenty of SH3 (POSH) help
direct the specificity of this pathway (95). The specificity of JNK's interaction with these scaffold proteins and its up
and downstream partners is also mediated, in part, through specific docking sites, including D motifs, MAPK-
docking sites, and others (332). Like all protein kinases, JNK activity is also counterregulated by phosphatases
including dual specific phosphatases MKP1, -2, -5, and -7 (311).
C. p38
Around the same time that JNK was discovered, another subfamily of SAPKs from the MAPK family was also
identified. p38 was originally isolated as a tyrosine phosphorylated protein found in LPS-stimulated macrophages
(147,148). At the same time, it was also reported as a molecule that binds pyridinyl imidazoles which inhibit the
production of proinflammatory cytokines (229). Since then, four different p38 isoforms have been identified,including the prototypic p38 (often referred to as simply p38), p38 (184), p38 (237), and p38 (228). p38 and
p38 are ubiquitously expressed, while p38 is expressed primarily in skeletal muscle and p38 is found in lung,
kidney, testis, pancreas, and small intestine (309). The four isoforms share structural similarities (>60% homology
within the group and even higher in their kinase domains) and substrate similarities as well. However, it is unclear in
vivo if activity towards a given substrate can vary between isoforms and if each isoform also has its own set of
specific substrates. This is demonstrated by gene knockout experiments in which deletion of the p38 gene leads to
embryonic lethality due to placental and erythroid differentiation defects (286,397), but mice carrying deletion of
any of the other three isoforms are phenotypically normal (139). Like other MAPK subfamilies, p38 kinases also
play numerous biological roles. Most prominently, p38 signaling is involved in the immune response, promoting
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expression of proinflammatory cytokines [interleukin (IL)-1, tumor necrosis factor (TNF)-, and IL-6], cell
adhesion molecules (VCAM-1), and other inflammatory related molecules and regulating the proliferation,
differentiation, and function of immune cells (221,342). p38 also plays a role in many other biological functions,
namely, apoptosis, cell survival, cell cycle regulation, differentiation, senescence, and cell growth and migration
(406,459). Physiologically, this translates into a role for p38 in chronic inflammatory diseases (rheumatoid arthritis,
Crohn's disease, psoriasis, and chronic asthma), tumorgenesis, cardiovascular disease, and Alzheimer's disease (83).
As a stress-activated kinase, p38 responds to most of the same stimuli as JNK as well as others that are specific to
p38. p38 can be activated by such stimuli as UV radiation, heat, osmotic shock, pathogens, inflammatory cytokines,
growth factors, and others. Making this pathway complicated, p38 can respond to over 60 different extracellular
stimuli in a cell-specific manner, making it challenging to elucidate its exact functional role in vivo (309).
Regardless of the exact stimuli, the canonical pathway of p38 activation is the same as for ERK and JNK (Fig. 2C).
A number of upstream kinases are implicated in the phosphorylation cascades leading to the activation of p38,
including MEKK14, TAK1, and ASK1 at the MAP3K level and MKK3, -6, and, possibly, -4 at the MAP2K level.
These MAP2Ks activate p38 by phosphorylation of its conserved Thr-Gly-Tyr motif. Of interesting note, p38 can be
activated in noncanonical ways as well. One way is TAB-1-mediated autophosphorylation (138,399), and another is
T-cell receptor-induced activation of p38 through ZAP70 (353). Once activated, p38 can function in the cytoplasm
or translocate to the nucleus. Substrates for p38 include transcription factors, other nuclear proteins, and cytoplasmic
proteins (309).
The magnitude of the signal and the specificity of the p38 pathway are determined by similar mechanisms as both
ERK and JNK. While scaffold proteins have been shown to be important in p38 signaling, there have only been
three such proteins identified so far: osmosensing scaffold for MEKK1 (OSM), JIP2, and JLP (95). p38 also utilizesspecific domains, such as CD motifs, ED motifs, and D motifs to facilitate its interaction with other proteins (332).
Finally, protein phosphatases are yet another form of p38 regulation, including dual specific MKPs (MKP1, -2, -5, -
7) and protein Ser/Thr phosphatases (PP2C) (186,311).
D. ERK5
ERK5 is the final classic MAPK subfamily and the least studied among the four. Discovered in the mid 1990s by
two groups simultaneously, many questions remain to be answered, although progress is rapidly being made on
many fronts. The first group identified ERK5 using a yeast two-hybrid screen with the upstream activator MEK5 as
the bait (25), while the second group used a degenerate PCR strategy to clone novel MAPKs (230). The most
distinguishing feature of this MAPK is its size, 816 amino acids, making it more than twice the size of the other
MAPK family members (thus the alternative name big MAPK or BMK). This increased size is due to a large 396-
amino acid COOH-terminal extension. While only one ERK5 gene has been identified, it undergoes alternativesplicing to produce four different protein species: ERK5a, ERK5b, ERK5c, and ERK-T. ERK5a is the most
prominently expressed, and the other three appear to function as negative regulators of ERK5a (268,448). This
kinase is ubiquitously expressed, and gene knockout studies show global deletion of ERK5 is embryonic lethal due
to what was initially thought to be cardiac defects (335). However, cardiomyocyte specific inactivation of ERK5
results in normal development, indicating that the lethality from the global knockout is due to defects in vascular
formation (154,155). Diverse biological roles of ERK5 are also identified, including cell survival, differentiation,
proliferation, and growth. ERK5 is reported to play a physiological role in neuronal survival, endothelial cell
response to sheer stress, prostate and breast cancer, cardiac hypertrophy, and atherosclerosis (155,304,424).
ERK5 is activated in response to both growth and stress stimuli. This includes a wide variety of growth factors
[epidermal growth factor, nerve growth factor, vascular endothelial growth factor (VEGF), FGF-2], serum, phorbol
ester, hyperosmosis, oxidative stress, laminar flow sheer stress, and UV radiation (155). Whatever the activating
stimuli, ERK5 follows the same canonical three-tiered pathway as the other MAPKs (Fig. 2D). Because of the
relative paucity of investigation for this pathway, there are fewer known upstream kinases. The most well-studied
MAP3Ks are MEKK2 and MEKK3, which activate the only known MAP2K, MEK5, which then phosphorylatesand activates ERK5. Once activated, ERK5 exerts its kinase activity on a number of other protein kinases and
transcription factors in both the cytosol and the nucleus. Furthermore, unlike other MAPKs, ERK5 has been shown
to function directly as a transcriptional activator (3,193).
ERK5 signaling, in true MAPK fashion, is influenced by such things as scaffold proteins, docking sites,
phosphatases, and other members of the MAPK family. However, because ERK5 is less well studied than the other
MAPKs previously discussed, less is known about these forms of regulation. Adaptor and scaffold proteins such as
Lck-associated adaptor (Lad) and Grb-2-associated binder 1 (Gab 1) as well as muscle specific A-kinase anchoring
protein (mAKAP) have all been shown to play an integral role in ERK5 signaling (424). Furthermore, MEK5 (the
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MAP2K of ERK5) uses its Phox/Bem 1P (PB1) domain to bind and tether together the upstream MAP3K
(MEKK2/3) and the downstream ERK5 to facilitate signaling (294,295). While regulation of ERK5 activity has
been shown to be regulated by specific protein phosphatases, such as MKP1 and -3 (192)and the phosphotyrosine
specific phosphatases PTP-SL (59), much less is known about this type of regulation than is with the other MAPKs.
Previous SectionNext Section
III. MITOGEN ACTIVATED PROTEIN KINASES IN HEART DEVELOPMENT
Mammalian cardiogenesis is a complex and highly coordinated biological process. With the advancement of
regenerative medicine and the utilization of stem cell therapy in treatment of cardiovascular diseases, understanding
the basic biology behind cardiac development has become more important than ever. While there are many signaling
events occurring during development, this review will focus only on the role that MAPKs play during this process
(Fig. 3). For extensive coverage, readers are directed to a number of excellent recent reviews on this issue
(56,108,308,379,380).
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Fig. 3.MAPK signaling during heart development. Proposed MAPK signaling events during various stages of heart
development. FHF, first heart field; SHF, second heart field; CNC, cardiac neural crest; V, ventricle; A, atria; RA,
right atrium; LA, left atrium; CT, conotruncus; RV, right ventricle; LV, left ventricle; AVV, atrioventricular valves;
Ao, aorta; PA, pulmonary artery; DA, ductus arteriosus. [Modified from Srivastava (379).]
During development, the heart is the first organ to form. It does so by a series of well-defined processes that can
broadly be grouped as 1) determination of cardiac cell fate at cardiac crescent and second heart field, 2)
differentiation of cardiomyocytes, and 3) morphogenesis and growth (56,137,379,396,419) The entire process,
including the simultaneous development of the nonmuscle structures of the heart, results from the delicate balance
between positive and negative regulatory signals coming from both within the structure and from the tissue
surrounding the developing heart (108,375). Numerous studies in myocardial development have elucidated a
number of important signaling pathways and transcription factors that are involved in coordinating heart formation.
Induction of cardiac fate involves the integration of a variety of signaling pathways, including Hedgehog, bone
morphogenic protein (BMP), FGF, and Wnt (108). This signaling culminates in the induction of cardiogenic
transcription factors including Nkx2.5, GATA4, serum response factor (SRF), Tbx5, and others. Much of the same
signaling that activates cardiac induction continues throughout the subsequent morphogenesis and growth (reviewed
in Ref.51). In the following sections we look at how the various MAPK family members participate in this process.
A. ERK1/2
Most contributions of the ERK1/2 pathway to heart development are due to its role in growth factor signaling. FGFs
are a large family of growth factors involved in a wide variety of cellular processes during development, including
proliferation, differentiation, cell survival, apoptosis, and cell migration (50). FGF ligands differentially bind to and
activate four different FGF receptors. These activated receptor tyrosine kinases transduce their signal through three
main downstream pathways: the Ras/Raf/ERK pathway, the phospholipase C (PLC)-/Ca2+pathway, or the
phosphatidylinositol 3-kinase (PI3K)/Akt pathway (85).
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FGF signaling contributes to cardiac development in a number of different ways. During early development, FGF
signaling has been shown to be important in cardiogenic induction. Originally thought to be due only to signaling of
BMPs, induction of progenitor cells to adopt a cardiac fate has more recently been shown to involve a cooperative
interaction between BMPs and FGFs (32,253). In both mouse and chicken models, various FGFs have been shown
to cooperate with BMP-2 to induce mesodermal cells to adopt a cardiac cell fate. While the exact downstream
mediators of FGF signaling in cardiac fate determination remain to be precisely elucidated, one study indicates that
it may not be due to ERK signaling. In mouse P19CL6 cells, a type of embryonic carcinoma cells which retain
mulitpotency (267), it was shown that the PI3K pathway is essential for early stage activation of Nkx2.5 and
GATA4 and subsequent cardiac differentiation in this setting (292). Likewise, treatment of this cell line with
PD98059, an ERK1/2 inhibitor, did not prevent cardiomyocyte differentiation in one study (91)and only partially
prevented differentiation in another report (115). However, these in vitro observations may not fully reveal what is
happening in vivo. This can be illustrated by the fact that ERK1/2 signaling has been shown to be vital to myocyte
differentiation using other experimental models. In studies using embryonic stem (ES) cells isolated from
both fgfr+/or fgfr/ mice, it was found that FGFR-1-deficient embryoid bodies (EBs) failed to differentiate into
clusters of beating myocytes while those with one copy of the gene appeared to differentiate normally (94). These
authors further elucidated the signaling involved in this differentiation process and found that the MEK1/2 inhibitor
U0126 blocked cardiogenic differentiation of the fgfr+/EBs. Interestingly, they found that use of the MEK1
inhibitor PD098059 did not affect differentiation, which may explain the results seen in P19CL6 cells previously
discussed. The role of ERK1/2 signaling in this process was further supported by using the PKC inhibitor GF109, as
PKC is known to regulate the Ras/Raf-1/MEK/ERK cascade at different levels (361). In the same study, GF109 also
blocked cardiac differentiation of the fgfr+/ EBs, while treatment with phorbol ester, a PKC activator, partiallyrescues the differentiation of fgfr/EBs in a U0126-sensitive manner. These data suggest a role for FGF signaling
via ERK1/2 in cardiogenic differentiation. Likewise, recent studies using mouse ES cells have also suggested that
ERK plays a role in leukemia inhibitory factor (LIF)-BMP-2 mediated differentiation into cardiomyocytes (331)and
other lineage commitment (215,381). From these studies, PI3K/AKT/GSK in addition to LIF/JAK/STAT and
BMP/Smad prove to be critical factors to maintain ES cell pluripotency and self-renewal and keep ES cells at a so-
called ground state. Such effect is achieved at least in part by blocking FGF -mediated ERK activation and
subsequent cell differentiation (130). While these in vitro studies supply us with some insight regarding induction of
cardiomyocyte cell fate, it still remains to be determined what, if any, role ERK1/2 plays in FGF signaling during
cardiac cell fate determination in vivo. Along with cardiac lineage induction, FGF signaling through the
Ras/Raf/ERK pathway plays a role in morphogenesis and growth throughout cardiac development. FGFs and their
receptors are expressed throughout development in the epicardium, endocardium, and myocardium (226,386). In
many cases, FGF signaling has been shown to occur in both autocrine and paracrine fashions. Sugi et al. (386)have
shown that endocardium derived FGF-4 signals to the endocardium and endocardial mesenchyme leading toproliferation and expansion of the cushion mesenchyme during valve leaflet formation (386). While this particular
study did not look at the specific signaling events taking place, recent studies have shown that, in assays of cells
from endocardial cushions, FGF-4 treatment increases phosphorylated ERK1/2 (38,246). Likewise, endocardium-
and epicardium-derived FGF-9 has been shown to contribute to the regulation of myocyte differentiation and
proliferation in the myocardium via FGFR1 and -2 (226). Therefore, FGF signaling may contribute to cardiac
morphogenesis; however, the connection for ERK pathway in this process remains to be further established.
Other than FGF signaling, other growth factors have also been shown to promote cardiac differentiation via the ERK
pathway. Using mouse ES cells, Chen et al. (68)have shown that VEGF promotes cardiomyocyte differentiation in
an ERK-dependent manner (68). In this study, treatment of mES cells with either recombinant VEGF 165or VEGF
cDNA resulted in a significant increase in expression of -myosin heavy chain (MHC), cTn-I, and Nkx2.5.
Corresponding to this, ERK1/2 phosphorylation was increased in VEGF-treated mES cells, and treatment with
PD098059, an ERK inhibitor, significantly decreased VEGF-induced -MHC expression. However, more in vivo
evidence is needed to support a role of VEGF-mediated signaling in cardiomyocyte differentiation. Likewise, otherreceptor tyrosine kinases can utilize ERK1/2 signaling during heart development. Epidermal growth factor receptors
(EGFRs), also known as ErbB receptors (ErbB1, -2, -3, and -4), are another group of important players in cardiac
development. Genetic inactivation of ErbB receptors (ErbB2, -3, and -4) and one of its known ligands, neuregulin-1,
leads to embryonic lethality between E10.5 and E13.5 due to cardiovascular defects in trabeculation and cardiac
cushion formation (319). ErbB receptors are known to signal in part through the ras/raf/MEK1/ERK pathway.
However, while numerous studies have verified the ERK pathway in ErbB signaling in neonatal and adult myocytes
(135), only a few studies have looked at its exact role in embryonic heart development. One recent study by Lia and
Pawson (223)has begun to shed some light on this question. By targeted inactivation of ShcA, an adaptor protein
associated with RTKs (including ErbB receptors), they demonstrated that this protein is involved primarily in pTyr
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signaling during cardiovascular development. Furthermore, ShcA null embyros died by E11.5 with cardiovascular
defects similar to those seen in the Neuregulin-1-, ErbB2-, and ErbB4-deficient embryos, including a thin left
ventricular myocardium associated with decreased trabeculation and defective formation of the cardiac cushions. In
these embryos, a significant decrease in phospho-ERK was observed in regions that correlate with cardiovascular
development and the normal pattern of ShcA expression. These findings indicate that ERK signaling indeed might
be part of the ErbB signaling during development.
One other area in cardiac development that has definitively pointed to the role of ERK1/2 signaling is during valve
development. Normal valve formation involves a process by which endocardial cushions are initially formed in the
atrioventricular canal (AVC) and the outflow tract (OFT), followed by cell proliferation and differentiation and the
eventual morphological remodeling (16). Development of cardiac cushions is a result of endothelial-mesenchymal
transdifferentiation (EMT) from a subset of endothelial cells. During this process, ErbB signaling is critical for
integration of signals from the extracellular matrix to regulate cardiac cushion proliferation and EMT (16). As
discussed previously, inactivation of ErbB and the corresponding ERK signaling results in disruption of cardiac
cushion formation. In the cardiac jelly, hyaluronic acid (HA) has been shown to induce ErbB signaling (269).
Camenisch et al. (60) have shown that in embryos deficient for Has2, an enzyme responsible for HA synthesis,
endocardial cells overlaying the cardiac cushion forming area display reduced EMT and migration (60), a phenotype
rescued by a constitutively active Ras. Likewise, the same study found that transfection with a dominant negative
Ras was able to block the ability of HA to promote EMT.
Other evidence for the role of ERK in valve development comes from situations where there is an overactivation of
Ras. Neurofibromin (NF1) functions as a Ras-specific GTPase activating protein (GAP) to inactivate Ras activity.
NF1 mutations cause the autosomal dominant disorder neurofibromatosis. Among other manifestations of thedisease, 2% of neurofibromatosis patients have been reported to suffer from cardiovascular malformations (245).
NF1-deficient mice die in utero at E14.5 with severe cardiac defects including enlarged cardiac cushions and
double-outlet right ventricles (54). Using cushion tissue explants from nf1/embryos at E10.5, Lakkis and Epstein
(224) identified a Ras-dependent increase in EMT as the cause of the enlarged cardiac cushion. They further
demonstrated that adenovirus transfection of the nf1/cushion explants with a dominant-negative form of Ras
inhibited EMT while the transfection of wild-type explants with a constituently active form of Ras increased EMT.
In addition to NF1 mutations, missense mutations in Ptpn11, which encodes for the protein tyrosine phosphatase
Shp2, have been discovered in 50% of individuals suffering from Noonan syndrome, an autosomal dominant
disorder characterized by congenital heart defects, most commonly pulmonary valve stenosis (306,400). Shp2 is
generally a positive regulator of RTK signaling, and its recruitment is necessary for Ras activation, although the
underlying molecular mechanisms remain unclear. By expressing a gain-of-function mutant, Ptpn11D61G, Araki et
al. (14)were able to recapitulate many of the characteristics of Noonan syndrome in mice. Approximately 50% of
the Ptpn11D61G transgenic embryos manifested multiple cardiac defects, the severity of which depended on thenumber of copies of the mutant transgene gene. Furthermore, increased levels of phospho-ERK in the cardiac
cushion of Ptpn11D61Gembryos were accompanied by an increase in cell proliferation and a decrease in apoptosis.
These findings are in good agreement with similar findings by Krenz et al. (212), in which expression of a slightly
different gain of function mutant, Shp2 (Q79R), resulted in proliferation of valve primordia mesenchymal cells in an
ERK1/2-dependent manner. Furthermore, it has recently been shown that an inducible knock-in ofPtpn11D61Galso
overactivates ERK signaling in endothelial-derived cells, leading to extended EMT, a phenotype previously seen in
the mouse model of Noonan syndrome (13).
In addition to valve defects, Nakamura et al. (296) have demonstrated that Shp2 gain-of-function mutations in
cardiomyocytes during embryonic development lead to defects in ventricular compaction and ventral septal defects
but have no impact when expressed after birth. Expression of the Shp2 mutant in embryonic cardiomyocytes
resulted in specific ERK activation without any change in the activity of any of the other MAPKs or in the Akt,
JAK/STAT, or RhoA pathways. Furthermore, cardiac defects observed in the Shp2 mutant embryos were rescued by
crossing with ERK null allele (296). In addition to Shp2, mutations in other components of the Ras signalingpathway including K-Ras (63,302,363), Sos1 (343), and Raf1 (315,334) are also found in cases of Noonan
syndrome. Finally, mutations in H-Ras, K-Ras, B-Raf, and MEK1/2 have also been discovered to be involved in
other genetic disorders with cardiac developmental defects, such as LEOPARD syndrome, cardio-facio-cutaneous
(CFC) syndrome, and Costello syndrome (10,302,345). This is covered in more detail by several excellent reviews
(11,37,364,408).
While much evidence suggests that the ERK1/2 pathway plays an important role in cardiac development at various
stages, several key questions remain to be clarified. The specific contribution of ERK1/2 pathway in cardiac
development remains to be fully investigated in vivo. Genetic deletion of ERK1 does not affect cardiac development
while ERK2 deletion is embryonic lethal, but that is due to developmental defects of extraembryonic ectoderm and
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ectoplacental cone, not the cardiovascular system (139). Temporally regulated, cell-specific targeted and multiloci
genetic perturbation may be required to unravel the full function of ERK in different stages of cardiac development.
Furthermore, the direct and indirect interaction between ERK pathway and other signaling pathways, such as AKT
(359)and BMP (111), will also need to be examined as the compensatory feedback regulation among these players
may contribute to the delicate outcome of heart development (111,130,139,359). Therefore, there is much more to
learn regarding the exact role the ERK1/2 signaling plays in cardiogenesis.
B. JNK
The role that JNK plays in heart development is best characterized for its function in noncanonical Wnt signaling.
Wnts are a large family of secreted proteins that are involved in many developmental processes including
proliferation, differentiatation, cell migration, cell fate determination, and establishment of cell polarity (298). Wnt
ligands promote signal transduction through their receptors, the frizzled family of transmembrane proteins. In
canonical Wnt signaling, the cytoplasmic protein Dishevelled removes the inhibitory effect of glycogen synthase
kinase 3 (GSK3) on -catenin, which subsequently translocates to the nucleus and activates transcription (reviewed
in Refs.35,110,130). Wnt can also signal through noncanonical pathways, one mediated throug